Dysregulation of PD-L1 by UFMylation imparts tumor immune evasion and identified as a potential therapeutic target.

Immunotherapy of PD-L1/PD-1 blockage elicited impressive clinical benefits for cancer treatment. However, the relative low response and therapy resistance highlight the need to better understand the molecular regulation of PD-L1 in tumors. Here, we report that PD-L1 is a target of UFMylation. UFMylation of PD-L1 destabilizes PD-L1 by synergizing its ubiquitination. Inhibition of PD-L1 UFMylation via silencing of UFL1 or Ubiquitin-fold modifier 1 (UFM1), or the defective UFMylation of PD-L1, stabilizes the PD-L1 in multiple human and murine cancer cells, and undermines antitumor immunity in vitro and mice, respectively. Clinically, UFL1 expression was decreased in multiple cancers and lower expression of UFL1 negatively correlated with the response of anti-PD1 therapy in melanoma patients. Moreover, we identified a covalent inhibitor of UFSP2 that promoted the UFMylation activity and contributed to the combination therapy with PD-1 blockade. Our findings identified a previously unrecognized regulator of PD-L1 and highlighted UFMylation as a potential therapeutic target.

A neuroprotective role of Ufmylation through Atg9 in the aging brain of Drosophila.

Ufmylation is a recently identified small ubiquitin-like modification, whose biological function and relevant cellular targets are poorly understood. Here we present evidence of a neuroprotective role for Ufmylation involving Autophagy-related gene 9 (Atg9) during Drosophila aging. The Ufm1 system ensures the health of aged neurons via Atg9 by coordinating autophagy and mTORC1, and maintaining mitochondrial homeostasis and JNK (c-Jun N-terminal kinase) activity. Neuron-specific expression of Atg9 suppresses the age-associated movement defect and lethality caused by loss of Ufmylation. Furthermore, Atg9 is identified as a conserved target of Ufm1 conjugation mediated by Ddrgk1, a critical regulator of Ufmylation. Mammalian Ddrgk1 was shown to be indispensable for the stability of endogenous Atg9A protein in mouse embryonic fibroblast (MEF) cells. Taken together, our findings might have important implications for neurodegenerative diseases in mammals.

Preparation of polyclonal antibodies against the Drosophila deacetylases SIRT 6 and SIRT 7.

SIRT6 and SIRT7, as members of the Sirtuins family, are indispensable for the growth and development of Drosophila. They play crucial roles in maintaining genome stability, regulating metabolic senescence, and controlling tumorigenesis. To investigate their involvement in the Drosophila life cycle, we focused on describing the expression and purification of recombinant Drosophila SIRT6 and SIRT7 proteins. Subsequently, these proteins were utilized for generating polyclonal antibodies against Drosophila SIRT6 and SIRT7. The recombinant expression plasmid was introduced into E. coli cells to enable the production of SIRT6 and SIRT7 proteins. Following immunizations of New Zealand white rabbits and guinea pigs with the recombinant proteins as antigens, specific polyclonal antisera against both proteins were obtained. After purification, the specificity of SIRT6 and SIRT7 was confirmed using ELISA and western blot analyses, demonstrating strong specificity. These antibodies hold promise for the development of detection assays required for further research.

CDK5RAP3, a Novel Nucleoplasmic Shuttle, Deeply Regulates HSF1-Mediated Heat Stress Response and Protects Mammary Epithelial Cells from Heat Injury.

CDK5RAP3 was regarded as the most significant regulator of cellular responses against heat stress, which is associated with dysfunctions of the immune system and animal susceptibility to disease. Despite this, little known about how CDK5RAP3 regulates heat stress response. In this study, CDK5RAP3 conditional Knockout (CKO) mice, CDK5RAP3-/- mouse embryo fibroblasts (MEFs) and bovine mammary epithelial cells (BMECs) were used as an in vitro and in vivo model, respectively to reveal the role of CDK5RAP3 in regulating the heat stress response. The deletion of CDK5RAP3 unexpectedly caused animal lethality after 1.5-h heat stimulations. Furthermore, BMECs were re-cultured for eight hours after heat stress and was found that the expression of CDK5RAP3 and HSPs showed a similar fluctuating pattern of increase (0-2, 4-6 h) and decrease (2-4, 6-8 h). In addition to the remarkably enhanced expression of heat shock protein, apoptosis rate and endoplasmic reticulum stress, the deletion of CDK5RAP3 also affected nucleoplasmic translocation and trimer formation of heat shock factor 1 (HSF1). These programs were further confirmed in the mammary gland of CDK5RAP3 CKO mice and CDK5RAP3-/- MEFs as well. Interestingly, genetic silencing of HSF1 downregulated CDK5RAP3 expression in BMECs. Immunostaining and immunoprecipitation studies suggested a physical interaction between CDK5RAP3 and HSF1 being co-localized in the cytoplasm and nucleus. Besides, CDK5RAP3 also interacted with HSP90, suggesting an operative machinery at both transcriptional level and protein functionality of HSP90 per se. Together, our findings suggested that CDK5RAP3 works like a novel nucleoplasmic shuttle or molecular chaperone, deeply participating in HSF1-mediated heat stress response and protecting cells from heat injury.

Salubrinal, a novel inhibitor of eIF-2α dephosphorylation, promotes erythropoiesis at early stage targeted by ufmylation pathway.

Ufmylation was proved to play a crucial role in hematopoietic stem cell (HSC) survival and erythroid differentiation, ufmylation deficiency induces acute anemia and lethality of embryos and adults in mouse models. To screen some compounds to rescue phenotypes induced by gene deletion, in this study, we used DDRGK1F/F ; CreERT2 conditional knockout mice, DDRGK1F/F ; CreERT2 bone marrow (BM) and fetal liver cells (FL), Uba5, and DDRGK1 knockdown human CD34 cell in vivo and in vitro, we found salubrinal, a novel inhibitor of eIF-2α dephosphorylation, promoted erythropoiesis at early stage, and partly rescued the acute anemia induce by DDRGK1 deficiency through upregulation of ufmylation and erythroid transcription factors. In phenylhydrazine (PHZ)-induced hemolytic anemia mice, interestingly, salubrinal could significantly improve hemocrit and red blood cell (RBC) indices of the mice treated with PHZ via upregulation of ufmylation. Its novel function was verified to attenuate unfolded protein response (UPR) and cell death programs, and to keep endoplasmic reticulum (ER) homeostasis in HSCs. Taken together results, it suggested that salubrinal may be a promising antianemic agent targeted by ufmylation.

UFBP1, a Key Component of the Ufm1 Conjugation System, Is Essential for Ufmylation-Mediated Regulation of Erythroid Development.

The Ufm1 conjugation system is an ubiquitin-like modification system that consists of Ufm1, Uba5 (E1), Ufc1 (E2), and less defined E3 ligase(s) and targets. The biological importance of this system is highlighted by its essential role in embryogenesis and erythroid development, but the underlying mechanism is poorly understood. UFBP1 (Ufm1 binding protein 1, also known as DDRGK1, Dashurin and C20orf116) is a putative Ufm1 target, yet its exact physiological function and impact of its ufmylation remain largely undefined. In this study, we report that UFBP1 is indispensable for embryonic development and hematopoiesis. While germ-line deletion of UFBP1 caused defective erythroid development and embryonic lethality, somatic ablation of UFBP1 impaired adult hematopoiesis, resulting in pancytopenia and animal death. At the cellular level, UFBP1 deficiency led to elevated ER (endoplasmic reticulum) stress and activation of unfolded protein response (UPR), and consequently cell death of hematopoietic stem/progenitor cells. In addition, loss of UFBP1 suppressed expression of erythroid transcription factors GATA-1 and KLF1 and blocked erythroid differentiation from CFU-Es (colony forming unit-erythroid) to proerythroblasts. Interestingly, depletion of Uba5, a Ufm1 E1 enzyme, also caused elevation of ER stress and under-expression of erythroid transcription factors in erythroleukemia K562 cells. By contrast, knockdown of ASC1, a newly identified Ufm1 target that functions as a transcriptional co-activator of hormone receptors, led to down-regulation of erythroid transcription factors, but did not elevate basal ER stress. Furthermore, we found that ASC1 was associated with the promoters of GATA-1 and Klf1 in a UFBP1-dependent manner. Taken together, our findings suggest that UFBP1, along with ASC1 and other ufmylation components, play pleiotropic roles in regulation of hematopoietic cell survival and differentiation via modulating ER homeostasis and erythroid lineage-specific gene expression. Modulating the activity of this novel ubiquitin-like system may represent a novel approach to treat blood-related diseases such as anemia.

RCAD/BiP pathway is necessary for the proper synthesis of digestive enzymes and secretory function of the exocrine pancreas.

Alcoholism causes an imbalance of endoplasmic reticulum (ER) homeostasis in pancreatic acini. In those cells, the ER is involved in the synthesis and folding of pancreatic enzymes. Ubiquitin-fold modifier 1 (Ufm1) is part of a novel ubiquitin-like modification system involved in maintaining ER homeostasis. Among the components of the Ufm1 system, Regulator of C53 and DDRGK1 (RCAD) has recently been identified as a Ufm1-specific E3 ligase that promotes ufmylation of DDRGK1, an RCAD-interacting protein. We determined the importance of RCAD in the proper synthesis and secretion of pancreatic enzymes using mice with genetically deleted RCAD. The pancreas of RCAD-deficient mice was of normal size and histology. Using quantitative PCR and Western blotting, we found that amylase was upregulated in pancreas organs from RCAD-knockout (KO) mice. Constitutive amylase secretion was much higher in isolated pancreatic acini from RCAD KO mice, whereas CCK-stimulated amylase secretion was disturbed. RCAD deficiency caused a downregulation in expression of ER chaperone BiP, which affected ER homeostasis and activated both apoptosis and trypsin. We also found that both RCAD and DDRGK1 transcript levels were upregulated in pancreatic acini from alcohol-preferring rats. Elevated expression of RCAD and DDRGK1 was associated with increased ER stress and UPR activation. Because of the lack of BiP expression, caspase 3 and trypsin activation we enhanced in RCAD-deficient pancreatic acini upon treatment with ethanol and CCK. In conclusion, the RCAD/BiP pathway is required for proper synthesis and secretion of pancreatic enzymes. In alcoholism, increased levels of components of the Ufm1 system could prevent the deleterious effects of alcohol in the pancreas by regulating BiP levels.NEW & NOTEWORTHY RCAD/BiP pathway is required for the proper synthesis and secretion of amylase from pancreatic acini, as well as for the maintenance of the ER homeostasis. In alcoholism, the exocrine pancreas could increase the levels of components of the Ufm1 system to protect itself from alcohol's deleterious effects by regulating the expression of ER chaperone BiP.

Targeting translation: eIF4E as an emerging anticancer drug target.

The translation initiation factor eIF4E mediates a rate-limiting process that drives selective translation of many oncongenic proteins such as cyclin D1, survivin and VEGF, thereby contributing to tumour growth, metastasis and therapy resistance. As an essential regulatory hub in cancer signalling network, many oncogenic signalling pathways appear to converge on eIF4E. Therefore, targeting eIF4E-mediated cap-dependent translation is considered a promising anticancer strategy. This paper reviews the strategies that can be used to target eIF4E, highlighting agents that target eIF4E activity at each distinct level.

A selective inhibitor of the UFM1-activating enzyme, UBA5.

Protein conjugation with ubiquitin and ubiquitin-like small molecules, such as UFM1, is important for promoting cancer cell survival and proliferation. Herein, the development of the first selective micromolar inhibitor of the UBA5 E1 enzyme that initiates UFM1 protein conjugation is described. This organometallic inhibitor incorporates adenosine and zinc(II)cyclen within its core scaffold and inhibits UBA5 noncompetitively and selectively over other E1 enzymes and a panel of human kinases. Furthermore, this compound selectively impedes the cellular proliferation (above 50µM) of cancer cells containing higher levels of UBA5. This inhibitor may be used to further probe the intracellular role of the UFM1 pathway in disease progression.

A novel SMAD family protein, SMAD9 is involved in follicular initiation and changes egg yield of geese via synonymous mutations in exon1 and intron2.

Elevation of egg performance is vital to goose farming. Many poultry scientists are seeking for efficient molecular genetic markers associated with egg yield. In this study, mRNA differential display was adopted to investigate gene expression profiling in the follicular development of goose. For the first time, a novel SMAD family protein SMAD9 (EST CJ111007) was found to be involved in follicular initiation and used to be a candidate gene. Functional regions analysis of Smad9 indicated that SMAD9 protein is highly conserved in MH1 and MH2 domains, and the connection area is highly variable region. 6 pairs of primers (p1-p6) were designed to detect the SNPs of Smad9 by PCR-SSCP method. The results revealed that polymorphisms were discovered in the PCR products amplified with P1 primers in exon1 and P3 primers in intron2. In Smad9 exon1, 5 genotypes were found: FK, FF, JJ, JK and KK, including 2 SNPs: 243 bp G → A, 309 bp T → G, the mutations did not result in amino acid mutations; In intron2, 3 genotypes were found: AA, BB and AB, only 1 SNP (C → T). The annual egg yield of FK genotype geese or allele gene A in intron2 are significantly more than those of other genotypes on the average (p < 0.05). Taken together, it is suggested that Smad9 is a promising candidate gene affecting egg performance in goose.

Evolutionary adaptations generally reverse phenotypic plasticity to restore ancestral phenotypes during new environment adaptation in cattle.

Phenotype plasticity and evolution adaptations are the two main ways in which allow populations to deal with environmental changes, but the potential relationship between them remains controversial. Using a reciprocal transplant approach with cattle adapted to the Tibetan Plateau and adjacent lowlands, we aim to investigate the relative contributions of evolutionary processes and phenotypic plasticity in driving both phenotypic and transcriptomic changes under natural conditions. We observed that while numerous genetic transcriptomic changes were evident during the forward adaptation to highland environments, plastic changes predominantly facilitate the transformation of transcriptomes into a preferred state when Tibetan cattle are reintroduced to lowland habitats. Genes with ancestral plasticity are generally reversed by evolutionary adaptations and show a closer expression level to the ancestral stage in evolved Tibetan cattle. A similar trend was also observed at the phenotypes level, with a majority of biochemical and hemorheology phenotypes showing a tendency to revert to their ancestral patterns, suggesting the restoration of ancestral expression levels is a widespread evolutionary trend during adaptation. The findings of our study contribute to the debate regarding the relative contributions of plasticity and genetic changes in mammal environment adaptation. Furthermore, we highlight that the restoration of ancestral phenotypes represents a general pattern in cattle new environment adaptation.

[Comparison of four diagnostic criteria for idiopathic inflammatory myopathy].

OBJECTIVE: To compare the clinical values of four different criteria for diagnosing idiopathic inflammatory myopathy (IIM). METHODS: The four different criteria published in 1975, 1995, 1997 and 2004 were applied to 94 IIM patients and 98 patients with other myopathies in West China Hospital. RESULTS: The sensitivity of the four criteria for diagnosing IIM was 56. 4% (1975), 87. 2% (1995), 61.7 % (1997), and 52. 1% (2004) respectively. The specificity of the four criteria for diagnosing IIM was 78. 6% (1975), 20. 4% (1995), 78. 6% (1997), and 90. 8% (2004) respectively. The Youden index was 35.0% (1975), 7.6% (1995), 40. 3% (1997), and 42.9% (2004), with an odd product of 4. 74 (1975), 1. 75 (1995), 5. 91 (1997) and 10. 77 (2004) respectively. The Kappa value of the four criteria was 0. 351 (1975, P<0.05), 0. 075 (1995, P>0. 05), 0. 404 (1997, P<0.05 ) and 0. 433 (2004, P<0.05), and their area under the ROC curve was 0. 675 (1975, P=0. 00), 0. 538 (1995, P=0.36),0. 701 (1997, P=0.00) and 0. 715 (2004, P=0.00) respectively. CONCLUSION: The 2004 criteria have a better value in diagnosing IIM.

[Levels of acute-phase-reactants in patient with dermatomysitis and its correlations with IL-6 and dermatomyositis disease activity].

OBJECTIVE: To determine the association between acute-phase-reactants (APR) and interleukin-6 (IL-6) in patient with dermatomysitis (DM). METHODS: The levels of C-reactive protein (CRP), serum amyloid A protein(SAA) and serum ferritin (SF) in peripheral blood of 31 adult DM patients were determined by chemiluminescence immunoassay, and compared with those of 23 patients with systemic lupus erythematosus (SLE), 22 patients with rheumatoid arthritis (RA), and 18 patients with Sjagren syndrome (SS). The correlations between the levels of those APR and IL-6 were examined. We also measured dermatomyositis disease activity using myositis disease activity assessment tool (MDAAT), and examined its association with APR levels. RESULTS: DM patients had significantly lower level of CRP [(17. 08 +/- 17. 18) mg/L] than those patients with RA [(85. 95 +/-60.62) mg/L, P<0. 000 1], SLE [(51. 34+/-52. 98) mg/L, P=0. 006] and SS [(47. 00+/-47. 24) mg/L, P= 0.018]. DM patients had significantly lower level of SAA [(92. 04 +/- 98. 93) mg/L] than those patients with RA [(311.30 +/- 292. 45) mg/L, P= 0. 002] and SS [(284. 31 +/- 325. 30) mg/L, P= 0. 025]. DM patients had significantly higher level of SF [(510. 10 +/- 610. 73) ng/mL] than those patients with SS [(220. 33 +/- 164. 07) ng/ mL, P=0. 02], as well as those with RA and SLE albeit without statistical significance. All of the three APRs were positive correlated with IL-6 level. No significant associations between APR and systemic or global disease activities were found, although CRP was associated with constitutional disease activity and SF was associated with pulmonary disease activity. CONCLUSION: DM patients have lower levels of elevated APR than the other three common connective tissue diseases, which is associated with IL-6 but not with global disease activity.

Biocontrol Capabilities of Bacillus subtilis E11 against Aspergillus flavus In Vitro and for Dried Red Chili (Capsicum annuum L.).

As a condiment with extensive nutritional value, chili is easy to be contaminated by Aspergillus flavus (A. flavus) during field, transportation, and storage. This study aimed to solve the contamination of dried red chili caused by A. flavus by inhibiting the growth of A. flavus and detoxifying aflatoxin B1 (AFB1). In this study, Bacillus subtilis E11 (B. subtilis) screened from 63 candidate antagonistic bacteria exhibited the strongest antifungal ability, which could not only inhibit 64.27% of A. flavus but could also remove 81.34% of AFB1 at 24 h. Notably, scanning electron microscopy (SEM) showed that B. subtilis E11 cells could resist a higher concentration of AFB1, and the fermentation supernatant of B. subtilis E11 could deform the mycelia of A. flavus. After 10 days of coculture with B. subtilis E11 on dried red chili inoculated with A. flavus, the mycelia of A. flavus were almost completely inhibited, and the yield of AFB1 was significantly reduced. Our study first concentrated on the use of B. subtilis as a biocontrol agent for dried red chili, which could not only enrich the resources of microbial strains for controlling A. flavus but also could provide theoretical guidance to prolong the shelf life of dried red chili.

Loss of Ufl1/Ufbp1 in hepatocytes promotes liver pathological damage and carcinogenesis through activating mTOR signaling.

BACKGROUND: Ufm1-specific ligase 1 (Ufl1) and Ufm1-binding protein 1 (Ufbp1), as putative targets of ubiquitin-fold modifier 1 (Ufm1), have been implicated in several pathogenesis-related signaling pathways. However, little is known about their functional roles in liver disease. METHODS: Hepatocyte-specific Ufl1Δ/Δhep and Ufbp1Δ/Δhep mice were used to study their role in liver injury. Fatty liver disease and liver cancer were induced by high-fat diet (HFD) and diethylnitrosamine (DEN) administration, respectively. iTRAQ analysis was employed to screen for downstream targets affected by Ufbp1 deletion. Co-immunoprecipitation was used to determine the interactions between the Ufl1/Ufbp1 complex and the mTOR/GßL complex. RESULTS: Ufl1Δ/Δhep or Ufbp1Δ/Δhep mice exhibited hepatocyte apoptosis and mild steatosis at 2 months of age and hepatocellular ballooning, extensive fibrosis, and steatohepatitis at 6-8 months of age. More than 50% of Ufl1Δ/Δhep and Ufbp1Δ/Δhep mice developed spontaneous hepatocellular carcinoma (HCC) by 14 months of age. Moreover, Ufl1Δ/Δhep and Ufbp1Δ/Δhep mice were more susceptible to HFD-induced fatty liver and DEN-induced HCC. Mechanistically, the Ufl1/Ufbp1 complex directly interacts with the mTOR/GßL complex and attenuates mTORC1 activity. Ablation of Ufl1 or Ufbp1 in hepatocytes dissociates them from the mTOR/GßL complex and activates oncogenic mTOR signaling to drive HCC development. CONCLUSIONS: These findings reveal the potential role of Ufl1 and Ufbp1 as gatekeepers to prevent liver fibrosis and subsequent steatohepatitis and HCC development by inhibiting the mTOR pathway.

UFL1, a UFMylation E3 ligase, plays a crucial role in multiple cellular stress responses.

The UFM1 conjugation system(UFMylation)is a novel type of ubiquitin-like system that plays an indispensable role in maintaining cell homeostasis under various cellular stress. Similar to ubiquitination, UFMylation consists of a three-step enzymatic reaction with E1-like enzymes ubiquitin-like modifier activating enzyme5 (UBA5), E2-like enzymes ubiquitin-fold modifier-conjugating enzyme 1(UFC1), and E3-like ligase UFM1-specific ligase 1 (UFL1). As the only identified E3 ligase, UFL1 is responsible for specific binding and modification of the substrates to mediate numerous hormone signaling pathways and endocrine regulation under different physiological or pathological stress, such as ER stress, genotoxic stress, oncogenic stress, and inflammation. Further elucidation of the UFL1 working mechanism in multiple cellular stress responses is essential for revealing the disease pathogenesis and providing novel potential therapeutic targets. In this short review, we summarize the recent advances in novel UFL1 functions and shed light on the potential challenges ahead, thus hopefully providing a better understanding of UFMylation-mediated cellular stress.

Metabonomic analysis of human and 12 kinds of livestock mature milk.

Mature milk, as a nutrient-rich endogenous metabolite, has various beneficial effects on the human body. In order to investigate the specific nutrients provided by different dairy products to humans, we used UHPLC-Q-TOF MS to analyze the highly significantly differentially expressed metabolites in 13 species of mammalian mature milk, which were grouped into 17 major metabolite classes with 1992 metabolites based on chemical classification. KEGG shows that 5 pathways in which differentially significant metabolites are actively involved are ABC transporters, Purine metabolism, Pyrimidine metabolism, Phosphotransferase system, Galactose metabolism. The study found that pig milk and goat milk are closer to human milk and contain more nutrients that are beneficial to human health, followed by camel milk and cow milk. In the context of dairy production, the development of goat milk is more likely to meet human needs and health.

CDK5RAP3, a key defender of udder, modulates NLRP3 inflammasome activation by regulating autophagolysosome degradation in S. agalactiae-infected mastitis.

Streptococcus agalactiae, as one of the main pathogens of clinical and subclinical mastitis, affects animal welfare and leads to huge economic losses to farms due to the sharp decline in milk yield. However, both the real pathogenic mechanisms of S. agalactiae-induced mastitis and the regulator which controls the inflammation and autophagy are largely unknown. Served as a substrate of ubiquitin-like proteins of E3 ligase, CDK5RAP3 is widely involved in the regulation of multiple signaling pathways. Our findings revealed that CDK5RAP3 was significantly down-regulated in mastitis infected by S. agalactiae. Surprisingly, inflammasome activation was triggered by CDK5RAP3 knockdown: up-regulated NLRP3, IL1ß and IL6, and cleaved caspase1 promoting by NF-κB, thereby resulting in pyroptosis. Additionally, the accumulation of autophagy markers (LC3B and p62) after CDK5RAP3 knockdown suggested that the autophagolysosome degradation pathway was inhibited, thereby activating the NF-κB pathway and NLRP3 inflammasome. Hence, our findings suggest that downregulation or ablation of CDK5RAP3 inhibits autophagolysosome degradation, causes inflammation by activating the NF-κB /NLRP3 inflammasome, and triggers cell death. In conclusion, CDK5RAP3 holds the key to understanding the interaction between autophagy and immune responses, its anti-inflammatory role in this study will throw new light on the clinical drug discovery to cure S. agalactiae mastitis.

Polymorphism in the exon 4 of ß-lactoglobulin variant B precursor gene and its association with milk traits and protein structure in Chinese Holstein.

ß-lactoglobulin (ß-LG) is the major whey protein in the milk. In order to investigate the polymorphism of ß-LG variant B precursor (ß-LG B*: GenBank accession no. DQ489319) gene and its effects on the milk traits, the single-strand conformation polymorphism method (PCR-SSCP) were adopted to analyze polymorphism between 5229th and 5476th bp in the ß-LG B* gene in Chinese Holstein. Four genotypes were found (AA, AB, AC and ABC) and 3 single nucleotide polymorphisms (SNPs) were detected (g.5239C>A, g.5240A>C, g.5305C>T and mix type g.5305C/T) in the exon 4 of ß-LG B* gene. It was also found that the protein contents of AB, AC and ABC dairy cows were higher than AA (P < 0.05), and AC cows were the highest among them. Three SNPs (g.5239C>A, g.5240A>C and g.5305C>T) might affect the milk trait and all of them were high polymorphism (0.5 < PIC < 1.0). In further researches, the three SNPs also caused amino acid change (Asp>Glu, Thr>Pro and Ala>Val) respectively, and the spatial secondary and tertiary structure forecasting result also showed that single amino acid change influence protein spatial structure change in Chinese Holstein. Taken together, it is suggested that these SNPs change ß-LG B* gene structure and expression. The polymorphism possibly holds the secret of milk protein and fat contents in the milk of Chinese Holstein.

Mutations in lipopolysaccharide-binding protein (LBP) gene change the susceptibility to clinical mastitis in Chinese Holstein.

Mastitis is an unsolved human challenge all dairy farms facing with, which leads to immeasurable economic loss to the farmers. LBP gene plays a vital role in the innate immune recognition of Gram-negative bacterium that is a major cause of bovine clinical mastitis, but little is known about LBP mutations and their effects on cows' susceptibility to clinical mastitis. In this study, PCR-SSCP method was adopted to analyze SNPs of LBP gene in Chinese Holstein for the first time. 17 SNPs were found in the promoter core region, exon1, exon2, exon3, exon4 and exon8. The mutation g.-81C → T in promoter leads to an AP-2 binding site lost. Two mutations, g.11T → C (4 Leu → Ser) and g.68G → C (23Gly → Ala) in signal peptide brought about molecular secondary structural change, meanwhile, g.11T → C made a Big-1 domain lost, and there was an N-myristoylation site at the g.68G/C locus. The three mutations above were in complete linkage disequilibrium in allele A. In mature LBP protein, five mutations were found: g.3034G → A(36Asp → Asn), g.3040A → G(38Asn → Asp), g.3056T → C(43Ile → Thr) in allele D; g.4619G → A(67Ala → Thr) in allele F; 19975G → A (282Val → Met) in allele J. And SNPs in allele D and F were in complete linkage disequilibrium, also in which 38Asn → Asp and 67Ala → Thr influenced the protein secondary structure. Prediction of the 3-D structure shows mutations 36Asp → Asn, 38Asn → Asp and 43 Ile → Thr were on the concave surface of LBP protein at barrel-N, 67Ala → Thr was in the apolar pocket at barrel-N. Motif analysis shows 36Asp → Asn causes loss of a CK2 phosphorylation site, 67 Ala → Thr forms a new PKC phosphorylation site. And 43Ile → Thr, 67Ala → Thr made hydrophobic amino acids to be hydrophilic amino acids. Interestingly, the morbidity of AB (mixed type g.-81C/T, g.11T/C, g.68G/C), CD (mixed type g.3034G/A, g.3040A/G, g.3056T/C) and EF (mixed type g.4619G/A) genotype cows are significant higher than others in this study (P < 0.01), and it can be deduced that the SNPs in these 3 genotypes might affect the secretion of LBP protein and regulate the binding ability of LBP protein to LPS. Taken together, it is revealed that these SNPs may hold the secret of susceptibility to clinical mastitis in Chinese Holstein.